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Main Authors: Liang, Qiantong, Yang, Johnny, Fan, Wai-Tong Louis, Lo, Wing-Cheong
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2303.13848
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author Liang, Qiantong
Yang, Johnny
Fan, Wai-Tong Louis
Lo, Wing-Cheong
author_facet Liang, Qiantong
Yang, Johnny
Fan, Wai-Tong Louis
Lo, Wing-Cheong
contents Defective interfering particles (DIPs) are virus-like particles that occur naturally during virus infections. These particles are defective, lacking essential genetic materials for replication, but they can interact with the wild-type virus and potentially be used as therapeutic agents. However, the effect of DIPs on infection spread is still unclear due to complicated stochastic effects and nonlinear spatial dynamics. In this work, we develop a model with a new hybrid method to study the spatial-temporal dynamics of viruses and DIPs co-infections within hosts. We present two different scenarios of virus production and compare the results from deterministic and stochastic models to demonstrate how the stochastic effect is involved in the spatial dynamics of virus transmission. We quantitatively study the spread features of the virus, including the formation and the speed of virus spread and the emergence of stochastic patchy patterns of virus distribution. Our simulations simultaneously capture observed spatial spread features in the experimental data, including the spread rate of the virus and its patchiness. The results demonstrate that DIPs can slow down the growth of virus particles and make the spread of the virus more patchy.
format Preprint
id arxiv_https___arxiv_org_abs_2303_13848
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Patch formation driven by stochastic effects of interaction between viruses and defective interfering particles
Liang, Qiantong
Yang, Johnny
Fan, Wai-Tong Louis
Lo, Wing-Cheong
Quantitative Methods
Defective interfering particles (DIPs) are virus-like particles that occur naturally during virus infections. These particles are defective, lacking essential genetic materials for replication, but they can interact with the wild-type virus and potentially be used as therapeutic agents. However, the effect of DIPs on infection spread is still unclear due to complicated stochastic effects and nonlinear spatial dynamics. In this work, we develop a model with a new hybrid method to study the spatial-temporal dynamics of viruses and DIPs co-infections within hosts. We present two different scenarios of virus production and compare the results from deterministic and stochastic models to demonstrate how the stochastic effect is involved in the spatial dynamics of virus transmission. We quantitatively study the spread features of the virus, including the formation and the speed of virus spread and the emergence of stochastic patchy patterns of virus distribution. Our simulations simultaneously capture observed spatial spread features in the experimental data, including the spread rate of the virus and its patchiness. The results demonstrate that DIPs can slow down the growth of virus particles and make the spread of the virus more patchy.
title Patch formation driven by stochastic effects of interaction between viruses and defective interfering particles
topic Quantitative Methods
url https://arxiv.org/abs/2303.13848